diff --git a/tests/classic_src/AbsBeamline/DipoleFieldTest.cpp b/tests/classic_src/AbsBeamline/DipoleFieldTest.cpp
index aee6e6555f0279ea059f95349aaad37ca43aba4f..47110b76fa0957b88ad07568c9c3e738882add16 100644
--- a/tests/classic_src/AbsBeamline/DipoleFieldTest.cpp
+++ b/tests/classic_src/AbsBeamline/DipoleFieldTest.cpp
@@ -8,17 +8,20 @@
#include "Algorithms/PartBunch.h"
#include "BeamlineCore/MultipoleRep.h"
#include "AbsBeamline/ElementBase.h"
+
+#include "opal_test_utilities/SilenceTest.h"
+
#include <fstream>
using namespace std;
vector< vector<double> > partialsDerivB(const Vector_t &R,const Vector_t B, double stepSize, SBendRep* dummyField)
-{
- // builds a matrix of all partial derivatives of B -> dx_i B_j
+{
+ // builds a matrix of all partial derivatives of B -> dx_i B_j
vector< vector<double> > allPartials(3, vector<double>(3));
double t = 0 ;
Vector_t P, E;
for(int i = 0; i < 3; i++)
- {
+ {
// B at the previous and next grid points R_prev, R_next
Vector_t R_prev = R, R_next = R;
R_prev[i] -= stepSize;
@@ -33,13 +36,13 @@ vector< vector<double> > partialsDerivB(const Vector_t &R,const Vector_t B, doub
}
vector< vector<double> > partialsDerivB_5(const Vector_t &R,const Vector_t B, double stepSize, SBendRep* dummyField)
-{
- // builds a matrix of all partial derivatives of B -> dx_i B_j
+{
+ // builds a matrix of all partial derivatives of B -> dx_i B_j
vector< vector<double> > allPartials(3, vector<double>(3));
double t = 0 ;
Vector_t P, E;
for(int i = 0; i < 3; i++)
- {
+ {
// B at the previous and next grid points R_prev, R_next
Vector_t R_pprev = R, R_prev = R, R_next = R, R_nnext = R;
R_pprev(i) -= 2 * stepSize;
@@ -50,13 +53,13 @@ vector< vector<double> > partialsDerivB_5(const Vector_t &R,const Vector_t B, do
dummyField->apply(R_prev, P, t, E, B_prev);
dummyField->apply(R_next, P, t, E, B_next);
dummyField->apply(R_pprev, P, t, E, B_pprev);
- dummyField->apply(R_nnext, P, t, E, B_nnext);
+ dummyField->apply(R_nnext, P, t, E, B_nnext);
for(int j = 0; j < 3; j++)
allPartials[i][j] = (B_pprev[j] - 8 * B_prev[j] + 8 * B_next[j] - B_nnext[j]) / (12 * stepSize);
}
return allPartials;
}
-
+
double calcDivB(Vector_t &R, Vector_t B, double stepSize, SBendRep* dummyField )
{
double div = 0;
@@ -65,7 +68,7 @@ double calcDivB(Vector_t &R, Vector_t B, double stepSize, SBendRep* dummyField )
for(int i = 0; i < 3; i++)
div += partials[i][i];
return div;
-}
+}
vector<double> calcCurlB(Vector_t &R, Vector_t B, double stepSize, SBendRep* dummyField)
{
@@ -81,6 +84,8 @@ vector<double> calcCurlB(Vector_t &R, Vector_t B, double stepSize, SBendRep* dum
TEST(Maxwell, Zeros)
{
+ OpalTestUtilities::SilenceTest silencer;
+
SBendRep* myMagnet = new SBendRep("myMagnet");
myMagnet->BendBase::setFieldMapFN("1DPROFILE1-DEFAULT");
myMagnet->BendBase::setLength(0.2);
@@ -96,7 +101,7 @@ TEST(Maxwell, Zeros)
PartBunch* bunch = new PartBunch(partData);
bunch->resetM(0.938);
bunch->setdT(1.0e-12);//time step
- double startField = 2.0, endField = 10.0 ;
+ double startField = 2.0, endField = 10.0 ;
myMagnet->Bend::initialise(bunch, startField, endField);
delete partData;
delete bunch;
@@ -108,9 +113,9 @@ TEST(Maxwell, Zeros)
int counter = 0;
//ofstream fout("some_data");
for(z = 0.0; z <0.0015; z+= 0.0015)
- for(x = 0.; x<0.04; x += 0.04)
+ for(x = 0.; x<0.04; x += 0.04)
for(double phi = -Physics::pi / 7.1 ; phi < 2/3. * Physics::pi; phi += Physics::pi/2000.)
- {
+ {
// step = phi/(Physics::pi/20);
//std::cout<<"Step #"<<step<<endl;
counter ++;
@@ -139,7 +144,7 @@ TEST(Maxwell, Zeros)
EXPECT_NEAR(curl[0], 0, 0.15);
EXPECT_NEAR(curl[1], 0, 0.15);
EXPECT_NEAR(curl[2], 0, 0.15);
-
+
}
//fout.close();
cout<<"bending radius: "<<myMagnet->Bend::designRadius_m<<endl;
@@ -165,6 +170,8 @@ TEST(Maxwell, Zeros)
TEST(Quad, Quadrupole)
{
+ OpalTestUtilities::SilenceTest silencer;
+
MultipoleRep* quad = new MultipoleRep();
//the following are used to initialise myMagnet
PartData* partData = new PartData();
@@ -199,6 +206,4 @@ TEST(Quad, Quadrupole)
gout.close();
cout<<"length: "<<quad->getElementLength()<<endl;
-}
-
-
+}
\ No newline at end of file
diff --git a/tests/classic_src/AbsBeamline/MultipoleTTest.cpp b/tests/classic_src/AbsBeamline/MultipoleTTest.cpp
index 6b30fafbd1e9ef3d39382a92f47deb07d2366194..25d4855302cbac3ee1279058c98475a47360cbfe 100644
--- a/tests/classic_src/AbsBeamline/MultipoleTTest.cpp
+++ b/tests/classic_src/AbsBeamline/MultipoleTTest.cpp
@@ -1,24 +1,27 @@
#include "gtest/gtest.h"
#include "AbsBeamline/MultipoleT.h"
+
+#include "opal_test_utilities/SilenceTest.h"
+
#include<fstream>
using namespace std;
vector< vector<double> > partialsDerivB(const Vector_t &R,const Vector_t B, double stepSize, MultipoleT* dummyField)
-{
- // builds a matrix of all partial derivatives of B -> dx_i B_j
+{
+ // builds a matrix of all partial derivatives of B -> dx_i B_j
vector< vector<double> > allPartials(3, vector<double>(3));
double t = 0 ;
Vector_t P, E;
for(int i = 0; i < 3; i++)
- {
+ {
// B at the previous and next grid points R_prev, R_next
Vector_t R_prev = R, R_next = R;
R_prev[i] -= stepSize;
R_next[i] += stepSize;
Vector_t B_prev, B_next;
dummyField->apply(R_prev, P, t, E, B_prev);
- dummyField->apply(R_next, P, t, E, B_next);
+ dummyField->apply(R_next, P, t, E, B_next);
for(int j = 0; j < 3; j++)
allPartials[i][j] = (B_next[j] - B_prev[j]) / (2 * stepSize);
}
@@ -26,13 +29,13 @@ vector< vector<double> > partialsDerivB(const Vector_t &R,const Vector_t B, doub
}
vector< vector<double> > partialsDerivB_5(const Vector_t &R,const Vector_t B, double stepSize, MultipoleT* dummyField)
-{
- // builds a matrix of all partial derivatives of B -> dx_i B_j
+{
+ // builds a matrix of all partial derivatives of B -> dx_i B_j
vector< vector<double> > allPartials(3, vector<double>(3));
double t = 0 ;
Vector_t P, E;
for(int i = 0; i < 3; i++)
- {
+ {
// B at the previous and next grid points R_prev, R_next
Vector_t R_pprev = R, R_prev = R, R_next = R, R_nnext = R;
R_pprev(i) -= 2 * stepSize;
@@ -49,7 +52,7 @@ vector< vector<double> > partialsDerivB_5(const Vector_t &R,const Vector_t B, do
}
return allPartials;
}
-
+
double calcDivB(Vector_t &R, Vector_t B, double stepSize, MultipoleT* dummyField )
{
double div = 0;
@@ -58,7 +61,7 @@ double calcDivB(Vector_t &R, Vector_t B, double stepSize, MultipoleT* dummyField
for(int i = 0; i < 3; i++)
div += partials[i][i];
return div;
-}
+}
vector<double> calcCurlB(Vector_t &R, Vector_t B, double stepSize, MultipoleT* dummyField)
{
@@ -73,6 +76,8 @@ vector<double> calcCurlB(Vector_t &R, Vector_t B, double stepSize, MultipoleT* d
TEST(MultipoleTTest, Field)
{
+ OpalTestUtilities::SilenceTest silencer;
+
MultipoleT* myMagnet = new MultipoleT("Quadrupole");
double centralField = 5;
double fringeLength = 0.5;
@@ -107,6 +112,8 @@ TEST(MultipoleTTest, Field)
}
TEST(MultipoleTTest, Maxwell) {
+ OpalTestUtilities::SilenceTest silencer;
+
MultipoleT* myMagnet = new MultipoleT("Quadrupole");
double centralField = 5;
double fringeLength = 0.5;
@@ -145,11 +152,13 @@ TEST(MultipoleTTest, Maxwell) {
}
TEST(MultipoleTTest, CurvedMagnet) {
+ OpalTestUtilities::SilenceTest silencer;
+
MultipoleT* myMagnet = new MultipoleT("Combined function");
myMagnet->setLength(4.0);
myMagnet->setBendAngle(0.0); // BUG small, non-zero bend angle ruins the convergence
myMagnet->setAperture(0.4, 0.4);
- myMagnet->setFringeField(2, 0.5, 0.5);
+ myMagnet->setFringeField(2, 0.5, 0.5);
myMagnet->setVarRadius();
myMagnet->setVarStep(0.1);
myMagnet->setTransMaxOrder(1);
@@ -185,6 +194,6 @@ TEST(MultipoleTTest, CurvedMagnet) {
<< " Del: " << div << " " << curlMag << std::endl;
}
}
- }
+ }
-}
+}
\ No newline at end of file
diff --git a/tests/classic_src/AbsBeamline/SBend3DTest.cpp b/tests/classic_src/AbsBeamline/SBend3DTest.cpp
index 8b623e341f7bf597ef69e240cbb6741ef1e3d4f0..ca7df0378a20aae3d68b8ab67d93524039f2386c 100644
--- a/tests/classic_src/AbsBeamline/SBend3DTest.cpp
+++ b/tests/classic_src/AbsBeamline/SBend3DTest.cpp
@@ -270,6 +270,8 @@ TEST(SBend3DTest, SBend3DPolyPatchTest) {
TEST(SBend3DTest, GeometryTest2) {
+ OpalTestUtilities::SilenceTest silencer;
+
// Sucked geometry information from
// Classic/AbsBeamline/Ring.cpp::appendElement
// Transform in OPAL-T coords
@@ -293,5 +295,4 @@ TEST(SBend3DTest, GeometryTest2) {
std::cerr << 24.*(1-cos(M_PI/12.)) << " " << 24.*sin(M_PI/12.) << " ** " << cos(M_PI/12.) << " " << sin(M_PI/12.) << " ** " << M_PI/12. << std::endl;
std::cerr << deltaPos << " ** " << deltaNorm << " ** " << endRot << std::endl;
-}
-
+}
\ No newline at end of file
diff --git a/tests/classic_src/AbsBeamline/ScalingFFAGMagnetTest.cpp b/tests/classic_src/AbsBeamline/ScalingFFAGMagnetTest.cpp
index 099631db04419217a2cd8b8b535d3a0394b2cbbb..9f186faf1a7635907015fec2e8a13d37b6c96b3e 100644
--- a/tests/classic_src/AbsBeamline/ScalingFFAGMagnetTest.cpp
+++ b/tests/classic_src/AbsBeamline/ScalingFFAGMagnetTest.cpp
@@ -36,12 +36,12 @@
#include "Classic/AbsBeamline/ScalingFFAGMagnet.h"
#include "Classic/AbsBeamline/Offset.h"
-class ScalingFFAGMagnetTest : public ::testing::Test {
-public:
- ScalingFFAGMagnetTest() : sector_m(NULL), fout_m() {
+class ScalingFFAGMagnetTest : public ::testing::Test {
+public:
+ ScalingFFAGMagnetTest() : sector_m(NULL), fout_m(), silencer_m() {
}
-
- void SetUp( ) {
+
+ void SetUp( ) {
sector_m = new ScalingFFAGMagnet("test");
// characteristic length is R*dphi => 0.6545 m
endfieldmodel::Tanh* tanh = new endfieldmodel::Tanh(psi0_m, psi0_m/5., 20);
@@ -59,8 +59,8 @@ public:
sector_m->setVerticalExtent(1.); // 1 m
sector_m->initialise();
}
-
- void TearDown( ) {
+
+ void TearDown( ) {
delete sector_m;
sector_m = NULL;
}
@@ -173,7 +173,7 @@ public:
Vector_t B(0., 0., 0.);
Vector_t BCart(0., 0., 0.);
double t = 0;
-
+
sector_m->getFieldValueCylindrical(posCyl, B);
bool outsideFieldMap = sector_m->apply(posCart, mom, t, E, BCart);
double delta = y/1000.;
@@ -208,7 +208,7 @@ public:
}
private:
-
+ OpalTestUtilities::SilenceTest silencer_m;
};
TEST_F(ScalingFFAGMagnetTest, ConstructorTest) {
@@ -332,7 +332,6 @@ TEST_F(ScalingFFAGMagnetTest, DFCoefficientsTanDeltaTest) {
}
TEST_F(ScalingFFAGMagnetTest, TanhTest) {
- OpalTestUtilities::SilenceTest silence;
double numericalDerivative = sector_m->getEndField()->function(-psi0_m, 0);
for (size_t order = 0; order < 5; ++order) {
double analyticalDerivative = sector_m->getEndField()->function(-psi0_m, order);
@@ -372,7 +371,6 @@ TEST_F(ScalingFFAGMagnetTest, ConvergenceYTest) {
}
TEST_F(ScalingFFAGMagnetTest, ConvergenceOrderTest) {
- OpalTestUtilities::SilenceTest silence;
for (double y = 0.5; y > 0.2; y /= 10.) { // 50 cm off midplane
std::cout << "order y divB |curlB| curlB" << std::endl;
std::vector<double> divBVec(13);
@@ -406,14 +404,13 @@ TEST_F(ScalingFFAGMagnetTest, ConvergenceOrderTest) {
}
TEST_F(ScalingFFAGMagnetTest, ConvergenceOrderHackedTest) {
- OpalTestUtilities::SilenceTest silence;
double y = 0.05;
bool cylindrical = false;
int maxOrder = 10;
// nb: if tan delta is 0., convergence reached at i = 7
for (double td = 0.2; td < 1.1; td += 0.2) { // 50 cm off midplane
std::cout << "order y B divB |curlB| curlB" << std::endl;
-
+
std::vector<double> divBVec(maxOrder);
std::vector<double> curlBVec(maxOrder);
double delta = y/100.;
@@ -534,5 +531,4 @@ TEST_F(ScalingFFAGMagnetTest, GeometryTest) {
EXPECT_EQ(rot(0), 0.);
EXPECT_EQ(rot(1), -psi0_m*4);
EXPECT_EQ(rot(2), 0.);
-}
-
+}
\ No newline at end of file
diff --git a/tests/classic_src/Fields/Interpolation/NDGridTest.cpp b/tests/classic_src/Fields/Interpolation/NDGridTest.cpp
index 1f2fa8d37c4e1f9ea276d59005c79223e4264c4b..5811a3157e717ab81418d0df9930aad4f43769f9 100644
--- a/tests/classic_src/Fields/Interpolation/NDGridTest.cpp
+++ b/tests/classic_src/Fields/Interpolation/NDGridTest.cpp
@@ -1,27 +1,27 @@
-/*
+/*
* Copyright (c) 2017, Chris Rogers
* All rights reserved.
- * Redistribution and use in source and binary forms, with or without
- * modification, are permitted provided that the following conditions are met:
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions are met:
* 1. Redistributions of source code must retain the above copyright notice,
- * this list of conditions and the following disclaimer.
- * 2. Redistributions in binary form must reproduce the above copyright notice,
- * this list of conditions and the following disclaimer in the documentation
+ * this list of conditions and the following disclaimer.
+ * 2. Redistributions in binary form must reproduce the above copyright notice,
+ * this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
- * 3. Neither the name of STFC nor the names of its contributors may be used to
- * endorse or promote products derived from this software without specific
+ * 3. Neither the name of STFC nor the names of its contributors may be used to
+ * endorse or promote products derived from this software without specific
* prior written permission.
*
- * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
- * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
- * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
- * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
- * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
- * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
- * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
- * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
- * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
- * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+ * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+ * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+ * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
+ * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+ * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+ * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+ * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+ * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+ * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
@@ -29,26 +29,28 @@
#include "Fields/Interpolation/NDGrid.h"
#include "Fields/Interpolation/Mesh.h"
+#include "opal_test_utilities/SilenceTest.h"
+
namespace ndgridtest {
-class NDGridTest : public ::testing::Test {
-public:
- NDGridTest() : grid_m(NULL) {
+class NDGridTest : public ::testing::Test {
+public:
+ NDGridTest() : grid_m(NULL) {
}
-
- void SetUp( ) {
+
+ void SetUp( ) {
std::vector< std::vector<double> > gridCoordinates(2);
gridCoordinates[0] = std::vector<double>(2, 0.);
- gridCoordinates[0][1] = 3.;
+ gridCoordinates[0][1] = 3.;
gridCoordinates[1] = std::vector<double>(3, 1.);
- gridCoordinates[1][1] = 5.;
+ gridCoordinates[1][1] = 5.;
gridCoordinates[1][2] = 9.;
grid_m = new interpolation::NDGrid(gridCoordinates);
gridCoordinates[1][2] = 10.; // force it to not be regular
grid2_m = new interpolation::NDGrid(gridCoordinates);
}
-
- void TearDown( ) {
+
+ void TearDown( ) {
delete grid_m;
grid_m = NULL;
delete grid2_m;
@@ -66,12 +68,16 @@ private:
};
TEST_F(NDGridTest, DefaultConstructorTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
interpolation::NDGrid grid;
EXPECT_EQ(grid.begin(), grid.end());
}
// also tests size
TEST_F(NDGridTest, Constructor1Test) {
+ OpalTestUtilities::SilenceTest silencer;
+
int size[] = {5, 6, 7, 8};
double spacing[] = {1., 2., 3., 4.};
double min[] = {-1., -2., -3., -4.};
@@ -86,6 +92,8 @@ TEST_F(NDGridTest, Constructor1Test) {
}
TEST_F(NDGridTest, Constructor2Test) {
+ OpalTestUtilities::SilenceTest silencer;
+
std::vector<int> size(2);
size[0] = 2;
size[1] = 3;
@@ -100,10 +108,12 @@ TEST_F(NDGridTest, Constructor2Test) {
ASSERT_EQ(grid1.size(i), size[i]);
EXPECT_NEAR(grid1.coord(1, i), gridCoordinates[i][0], 1e-12) << "Failed for i " << i;
EXPECT_NEAR(grid1.coord(i+2, i), gridCoordinates[i][size[i]-1], 1e-12) << "Failed for i " << i;
- }
+ }
}
TEST_F(NDGridTest, Constructor3Test) {
+ OpalTestUtilities::SilenceTest silencer;
+
std::vector< std::vector<double> > gridCoordinates(2);
gridCoordinates[0] = std::vector<double>(2, 0.);
gridCoordinates[1] = std::vector<double>(3, 1.);
@@ -115,10 +125,12 @@ TEST_F(NDGridTest, Constructor3Test) {
ASSERT_EQ(grid1.size(i), size);
EXPECT_NEAR(grid1.coord(1, i), gridCoordinates[i][0], 1e-12) << "Failed for i " << i;
EXPECT_NEAR(grid1.coord(i+2, i), gridCoordinates[i][size-1], 1e-12) << "Failed for i " << i;
- }
+ }
}
TEST_F(NDGridTest, CoordTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
std::vector< std::vector<double> > gridCoordinates(2);
gridCoordinates[0] = std::vector<double>(2, 0.);
gridCoordinates[1] = std::vector<double>(3, 1.);
@@ -128,14 +140,16 @@ TEST_F(NDGridTest, CoordTest) {
for (int i = 0; i < 2; ++i) {
EXPECT_NEAR(grid_var.coord(1, i), gridCoordinates[i][0], 1e-12) << "Failed for i " << i;
EXPECT_NEAR(grid_const.coord(1, i), gridCoordinates[i][0], 1e-12) << "Failed for i " << i;
- }
+ }
}
TEST_F(NDGridTest, CoordVectorTest) { // and newCoordArray
+ OpalTestUtilities::SilenceTest silencer;
+
std::vector< std::vector<double> > gridCoordinates(2);
gridCoordinates[0] = std::vector<double>(2, 0.);
gridCoordinates[1] = std::vector<double>(3, 1.);
- gridCoordinates[1][2] = 9.;
+ gridCoordinates[1][2] = 9.;
interpolation::NDGrid grid(gridCoordinates);
for (int i = 0; i < 2; ++i) {
std::vector<double> coords_v = grid.coordVector(i);
@@ -150,6 +164,8 @@ TEST_F(NDGridTest, CoordVectorTest) { // and newCoordArray
}
TEST_F(NDGridTest, CoordLowerBoundTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
// first dimension ... 0., 3.;
int index = -1;
grid_m->coordLowerBound(-1., 0, index);
@@ -186,6 +202,8 @@ TEST_F(NDGridTest, CoordLowerBoundTest) {
}
TEST_F(NDGridTest, LowerBoundTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
// first dimension ... 0., 3.;
// second dimension ... 1., 5., 9.
std::vector<int> index1(2, -2);
@@ -208,6 +226,8 @@ TEST_F(NDGridTest, LowerBoundTest) {
}
TEST_F(NDGridTest, MinMaxTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
EXPECT_EQ(grid_m->min(0), 0.);
EXPECT_EQ(grid_m->min(1), 1.);
EXPECT_EQ(grid_m->max(0), 3.);
@@ -215,6 +235,8 @@ TEST_F(NDGridTest, MinMaxTest) {
}
TEST_F(NDGridTest, SetCoordTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
double xNew[] = {5., 10., 12., 15.};
grid_m->setCoord(0, 4, xNew);
std::vector<double> xTest = grid_m->coordVector(0);
@@ -225,6 +247,8 @@ TEST_F(NDGridTest, SetCoordTest) {
}
TEST_F(NDGridTest, BeginEndTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
ASSERT_EQ(grid_m->begin().getState().size(), 2);
EXPECT_EQ(grid_m->begin().getState()[0], 1);
EXPECT_EQ(grid_m->begin().getState()[1], 1);
@@ -234,6 +258,8 @@ TEST_F(NDGridTest, BeginEndTest) {
}
TEST_F(NDGridTest, GetPositionTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
std::vector<double> position(3, -1);
interpolation::Mesh::Iterator it = grid_m->begin();
grid_m->getPosition(it, &position[0]);
@@ -248,6 +274,8 @@ TEST_F(NDGridTest, GetPositionTest) {
}
TEST_F(NDGridTest, GetSetConstantSpacingTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
EXPECT_TRUE(grid_m->getConstantSpacing());
grid_m->setConstantSpacing(false);
EXPECT_FALSE(grid_m->getConstantSpacing());
@@ -270,6 +298,8 @@ TEST_F(NDGridTest, GetSetConstantSpacingTest) {
}
TEST_F(NDGridTest, ToIntegerTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
interpolation::Mesh::Iterator it = grid_m->begin();
EXPECT_EQ(grid_m->toInteger(it), 0);
it[0] = 2;
@@ -278,6 +308,8 @@ TEST_F(NDGridTest, ToIntegerTest) {
}
TEST_F(NDGridTest, GetNearestTest) {
+ OpalTestUtilities::SilenceTest silencer;
+
// first dimension ... 0., 3.;
// second dimension ... 1., 5., 9.
@@ -303,5 +335,4 @@ TEST_F(NDGridTest, GetNearestTest) {
EXPECT_EQ(it[1], 3);
}
-} // namespace ndgridtest
-
+} // namespace ndgridtest
\ No newline at end of file
diff --git a/tests/classic_src/Fields/Interpolation/PPSolveFactoryTest.cpp b/tests/classic_src/Fields/Interpolation/PPSolveFactoryTest.cpp
index 84bf7766f342e7279129656dc123b1ab5f322aea..f3cd81da545d787980e8101a8080e3fac940fcda 100644
--- a/tests/classic_src/Fields/Interpolation/PPSolveFactoryTest.cpp
+++ b/tests/classic_src/Fields/Interpolation/PPSolveFactoryTest.cpp
@@ -123,6 +123,8 @@ class PPSolveFactoryTestFixture : public ::testing::Test {
// check linear fit exactly reproduces data on grid points
TEST_F(PPSolveFactoryTestFixture, TestSolvePolynomialLinear) {
+ OpalTestUtilities::SilenceTest silencer;
+
PPSolveFactory fac1(grid->clone(),
values,
1,
@@ -140,6 +142,8 @@ TEST_F(PPSolveFactoryTestFixture, TestSolvePolynomialLinear) {
// check quadratic fit exactly reproduces data on and off grid points (data
// comes from a quadratic polynomial as source)
TEST_F(PPSolveFactoryTestFixture, TestSolvePolynomialQuadratic) {
+ OpalTestUtilities::SilenceTest silencer;
+
PPSolveFactory fac2(grid->clone(),
values,
2,
@@ -179,6 +183,8 @@ TEST_F(PPSolveFactoryTestFixture, TestSolvePolynomialQuadratic) {
// check smoothed quadratic fit exactly reproduces data on and off grid points
// except near to the boundary
TEST_F(PPSolveFactoryTestFixture, DISABLED_TestSolvePolynomialQuadraticSmoothed) {
+ OpalTestUtilities::SilenceTest silencer;
+
PPSolveFactory fac2(grid->clone(),
values,
1,
@@ -379,4 +385,4 @@ TEST(PPSolveFactoryTest, TestThreeDSolveSinCos) {
}
std::cout << std::endl;
}
-}
+}
\ No newline at end of file
diff --git a/tests/opal_src/Distribution/BinomialTest.cpp b/tests/opal_src/Distribution/BinomialTest.cpp
index b9cf6634c2beb831b9dea85066249932c3b5ff0b..7128adc04c686790c2a4d2e0ac87425deb6e72e0 100644
--- a/tests/opal_src/Distribution/BinomialTest.cpp
+++ b/tests/opal_src/Distribution/BinomialTest.cpp
@@ -56,6 +56,7 @@ TEST(BinomialTest, FullSigmaTest1) {
dist.setDistType();
dist.checkIfEmitted();
size_t numParticles = 1000000;
+ dist.totalNumberParticles_m = numParticles;
dist.create(numParticles, Physics::m_p);
double R11 = sqrt(gsl_stats_variance(&(dist.xDist_m[0]), 1, dist.xDist_m.size())) * 1e3;
@@ -137,6 +138,7 @@ TEST(BinomialTest, FullSigmaTest2) {
dist.checkIfEmitted();
size_t numParticles = 1000000;
+ dist.totalNumberParticles_m = numParticles;
dist.create(numParticles, Physics::m_p);
double R11 = sqrt(gsl_stats_variance(&(dist.xDist_m[0]), 1, dist.xDist_m.size())) * 1e3;
diff --git a/tests/opal_src/Distribution/GaussTest.cpp b/tests/opal_src/Distribution/GaussTest.cpp
index 0c69d9bfc6db45c6ac397764d33799efaa00169e..5c049ae5c6d93bf8bffb0171066a83692d00c33d 100644
--- a/tests/opal_src/Distribution/GaussTest.cpp
+++ b/tests/opal_src/Distribution/GaussTest.cpp
@@ -54,6 +54,7 @@ TEST(GaussTest, FullSigmaTest1) {
dist.setDistType();
dist.checkIfEmitted();
size_t numParticles = 1000000;
+ dist.totalNumberParticles_m = numParticles;
dist.create(numParticles, Physics::m_p);
double R11 = sqrt(gsl_stats_variance(&(dist.xDist_m[0]), 1, dist.xDist_m.size())) * 1e3;
@@ -138,6 +139,7 @@ TEST(GaussTest, FullSigmaTest2) {
dist.checkIfEmitted();
size_t numParticles = 1000000;
+ dist.totalNumberParticles_m = numParticles;
dist.create(numParticles, Physics::m_p);
double R11 = sqrt(gsl_stats_variance(&(dist.xDist_m[0]), 1, dist.xDist_m.size())) * 1e3;